ES2341133T3 - OPERATING PROCEDURE OF AN AUTONOMOUS DOMOTIC CAPTOR DEVICE TO DETECT THE EXISTENCE AND / OR TO MEASURE THE INTENDISITY OF A PHYSICAL PHENOMENON. - Google Patents

Abstract

The method involves activating a normal operation mode of an autonomous home automation sensor device or an energy saving operation mode of the sensor device according to a value defined from determination of instantaneous power convertible into an electrical energy. The sensor device has reduced electrical consumption in the energy saving operation mode than in the normal operation mode. Measurement frequency of intensity of a physical phenomenon e.g. luminosity, is high in the normal operation mode than in the energy saving operation mode.

Description

Operating procedure of a autonomous home automation sensor device to detect the existence and / or to measure the intensity of a physical phenomenon.

The invention relates to a device of home automation and autonomous sensor for measuring the intensity of a physical phenomenon and intended, in particular, to drive a motorized sun protection device such as, so main, an awning or a roller blind.

The use of a device is known motorized sun protection to regulate the penetration of solar rays in a building through an opening made in the same. In the case of an automatic control, a brightness sensor to emit drive signals to the motorized sun protection device in order to move a mobile element to obtain a certain level of comfort. In order to reduce the wiring voltages of the installation, it is known the forecast of means that allow a communication without wire between the collector and the sun protection device. With in order to further limit the wiring voltages, it is known the use of sensors that work so autonomous. These autonomous collectors comprise a means of electrical energy storage, such as a battery and, eventually, means for the conversion of an energy (for example solar) in an electric energy.

It is known by the JP request 02-091348, a procedure of operation of a installation in which a collector periodically emits a status signal in order to ensure a safety function. The periodic reception of this signal by a home automation device assures the latter that the collector is operational. In the case in that the status signal is not received, the home automation device Enter a security mode.

The main problem that arises for these Autonomous collectors refers to the domain over energy. In In particular, it is necessary to ensure operational autonomy sufficient even when the conditions outside the device are such that practically, no one can be transformed energy in electrical energy (for example at night for collector devices comprising a photovoltaic panel). The solutions to this problem rest on the minimization of consumption of electrical energy and on the optimization of the load of the electrical energy reserves. However, the structures of the devices must be simple, inexpensive and sized reduced.

On the other hand, it is important that the new collectors, low energy consumption, are compatible with the existing receivers.

Various procedures are known, which allow save energy in home automation sensor devices and autonomous.

It is known, for example, from WO 2005/114610 a procedure in which a sensor device home automation emits, discreetly, information minimizing the relationship between the emission periods and the periods that separate Two broadcast periods. This results in the reduction of energy consumption

It is known from document US 2005/0030177 a home automation sensor device in which the emission frequency Information depends on the level of charge of your battery.

In the same way, it is known by the document DE 299 23 046 an autonomous home automation sensor device, which emits an alert signal when the energy level contained in Your batteries drop below a certain threshold.

Similarly, devices of autonomous collectors, which are powered by panels photovoltaic, for the documents "Solar powered low power sensor module with a radio communication and a user interface "and US 2006/148410.

In all these documents, the management of the Energy is not optimal.

The object of the invention consists in provide an operating procedure of a device  autonomous home automation sensor that palliates the listed problems before In particular, the invention proposes a operating procedure, which allows better management of energy sources for a better anticipation of variations in the amounts of energy that can be converted in electrical energy

The operating procedure, of in accordance with the invention, is defined by the claim one.

They have been defined by the claims Dependents 2 to 10 different modes of procedure execution in accordance with the invention.

The autonomous home automation sensor device, of In accordance with the invention, it is defined by means of the claim 11.

The attached drawing represents, by way of examples, an embodiment of a sensor device autonomous home automation in accordance with the invention and a mode of execution of a device operating procedure of this type.

Figure 1 is a schematic of a mode of realization of an autonomous home automation sensor device in accordance with the invention.

Figure 2 is a representative diagram of the activity of the autonomous home automation sensor device in two different operating modes.

Figure 3 is a representative table of the behavior of the autonomous home automation sensor device in two different operating modes.

Figure 4 is a partial detail scheme of an embodiment of a home automation sensor device autonomous in accordance with the invention.

The autonomous home automation sensor device 10, represented in figure 1, allows to detect a physical phenomenon and / or measure the intensity of a physical phenomenon, which may be this physical phenomenon, principally, lighting, wind, a mechanical vibration This device comprises, so main, a means 20 for the conversion of a non-energy electrical in an electrical energy, a means 30 for the electrical energy storage, a microcontroller 40, a emitter 50 of electromagnetic signals (for example radio), a detection means 60, a converter of the voltage 70 and a medium 80 for power determination instant convertible into electrical energy.

The means for energy conversion can use an energy such as light, heat, a vibration, a movement, an electromagnetic wave or any other form of energy available in or near a building, to turn it into an electric energy. Preferably, it converts light into electrical energy and a photovoltaic cell Preferably, the means of electrical energy storage comprises a capacitor or a drums. Also several capacitors can be used. He microcontroller comprises computer media modules that define the operation of the home automation sensor device autonomous. Preferably, the microcontroller is of the type with low energy consumption. For example, it can be tilted in a inertia mode and can work with different frequencies of watch. Eventually a microcontroller may be provided auxiliary to pilot emitter 50. In this case, the Auxiliary microcontroller can be integrated in the transmitter.

Preferably, the issuer is of the type of radio frequencies that emit radio waves at a frequency comprised  between 30 MHz and 2.4 GHz. This transmitter regularly emits a signal from status, which allows you to report on the operating status of the home automation device autonomous to any of the elements of the home automation network of which this device is part. Each signal emitted preferably comprises a plurality of frames containing respectively the same information in order to ensure a good transmission of this information despite possible electromagnetic disturbances. Preferably these frames also comprise an identifier.

The detection means 60 comprises one or more collectors In a preferred embodiment, at least one of the collectors constitute, or form part, of the means for determination of instantaneous power convertible into energy electric For example, if the means for energy conversion 20 allows the transformation of solar energy into electrical energy, one of the sensors allows to detect or measure a luminosity. Other parameters of physical phenomena, which can be detected or measure thanks to additional collectors, they are, in a main way, the wind speed, wind direction, temperature, presence of rain, the presence of snow, pressure, humidity, the presence of fire, the presence of smoke, the presence of a user, air quality, glass breakage, concentration in gas (for example in carbon dioxide, in monoxide of carbon, in oxygen or in volatile organic compounds).

In addition to a periodic broadcast of a signal from status, the autonomous home automation sensor device emits, thanks to its issuer, a signal relating to data supplied by or by the collectors. This signal can comprise the absolute values of the intensities of the measured physical phenomena. Likewise can understand logical information related to these phenomena physical (for example the presence or absence of smoke, temperature less than or greater than a set threshold). In the case of logical information that exceeds the thresholds, the signal can be sent only when the value has exceeded the threshold for a predetermined time. Advantageously, these thresholds can be regulated by the user. Preferably the autonomous home automation sensor device comprises a Elevator type voltage converter in order to adapt the medium output voltage for energy conversion to the necessary for loading the storage medium. In accordance with the loading of the storage medium, it is preferable not to use The voltage converter. The microcontroller presents, so preferred, means that enable or disable the converter voltage according to the load of the medium of storage.

An output of a sensing means sensor 60 is connected to the microcontroller. Thus, depending on the signal transmitted from this sensor to the microcontroller, the latter executes a first computer media module, which defines a first mode of operation of the autonomous home automation sensor device or a second computer media module, which defines a second mode of operation of the autonomous home automation sensor device. In the case where the means for conversion is a photovoltaic cell, the signal transmitted to the microcontroller will comprise information on the intensity of the illumination. This information is compared with a threshold to activate or not activate the first mode of operation or the second mode of operation. In both modes, the same functions are substantially secured. However, the second mode of operation allows greater energy savings. These energy savings are evidently realized by limiting the electrical consumption of the device in the second mode comparatively with that which this device consumes in the first mode, all other conditions being identical. Mainly, the electrical consumptions of the microcontroller 40 and / or of the emitter 50 and / or of the medium for voltage conversion 70 are limited in this second mode. Similarly, it is possible to limit the electrical consumption of any other means that consume the device's electrical energy. For this purpose, several actions can be performed simultaneously
or not:

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the period between two is increased emissions of status signals, that is to say that the frequency is reduced  of the emissions of the status signals,

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the number of frames is decreased issued on each status signal,

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the period between two is increased data signal emissions, ie the frequency is reduced of data signal emissions,

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The microcontroller works with different frequencies according to the function assured by the device  of autonomous home automation sensor (measurement, emission),

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the medium for the conversion of Energy feeds directly to the storage medium.

All these actions allow to limit, even individually, the electrical consumption of the device. By other part, any combination of several of these actions It also allows to limit the electrical consumption of the device.

The two modes of operation are described. in more detail in figures 2 and 3. In the mode of preferred embodiment in which the medium for conversion is a photovoltaic cell and in which one of the collectors is a photodiode, this sensor is used to determine which is the instantaneous power convertible into electrical energy. Nap instantaneous power, or a defined value from a sample of measured powers (for example a global average), is greater than a threshold, that is to say if the illumination measured by the photodiode is greater than a predetermined threshold, the sensor device works from Compliance with a first mode. On the contrary, if this power snapshot, or a defined value from a sample of measured powers, is lower than a threshold, that is if the lighting measured by the photodiode is less than this threshold By default, the pickup device works in accordance With a second mode.

In the first mode, lighting is measured by compliance with a t1 period thanks to the photodiode. He microcontroller then works in accordance with a first clock frequency f, for example 32 KHz, which defines a period t. Among the measurements, the microcontroller is tilted to a state low consumption, for example in inertia mode. In this mode, the relationship between periods of operation in a low state consumption and operation in accordance with the first clock frequency, is greater than 50. When the device autonomous home automation sensor transmits a status signal thanks to its emitter, the microcontroller then operates in accordance with a second clock frequency f greater than the first, for example 2 MHz. The T1 period that separates two consecutive emissions from one status signal can be at least 10 times greater than the one separate two different measures (T1> 10 x t1). By way of preferably, the measure of the instantaneous power convertible into electrical energy (which allows to determine if the device should or do not change operating mode) is carried out at the moment of sending the status signal.

In addition to these measurement actions and transmission, the autonomous home automation sensor device can emit other signals thanks to its transmitter, containing these signals measurement data made by the collectors or data deducted by comparing these measures with thresholds. For example, you are signals may indicate the appearance or disappearance of the sun to actuate, accordingly, a sun protection device.

In the second mode, the sensor device autonomous home automation does not transmit more than status signals and verifies if the change mode condition of functioning.

In the second mode, lighting is measured thanks to the photodiode in accordance with a much longer period t2 than the period t1. Preferably, the period t2 is a multiple of period t1. The frequency can be even zero. In In this case, lighting can only be measured when check if the change mode mode has been performed functioning. In order to reduce energy consumption in this period of low convertible power, the transmission period T2 of the status signals is much greater than that of the first mode. From in the same way the number of frames emitted in the signal is reduced of State.

Preferably, the period T2 is a multiple of the period T1. In this way, an old receiver, belonging to a product range of a generation prior to sensor device according to the invention, can work with this sensor device. In effect, this receiver will consider the missing frames in the second mode of operation in relation to the first mode of operation, whereas they are due to transmission errors. For example, a old generation receiver is planned to work with a old generation sensor device that emits every 15 minutes, the receiver considers that the sensor device is it is in status if it receives a signal at least every 45 minutes. Be understands that, if the sensor device complies with the invention issues every 15 minutes in a first mode and every 30 minutes or every 45 minutes in a second mode, this device can function in a manner compatible with the generation receiver previous.

Preferably, it is interesting to adapt the charging conditions of the energy storage medium to the amount of energy convertible into electrical energy. By consequently, in a preferred embodiment, the conditions of storage media load depend on the mode of operation of the autonomous home automation sensor device. At First mode of operation, the storage medium is loaded through a voltage booster or, directly, from the middle for energy conversion of compliance with the load level of the storage medium. At second mode of operation, the means for conversion is always loaded directly from the medium for the conversion of Energy.

It has been described, with reference to Figure 4, a circuit for instantaneous power determination convertible into electrical energy. In the case described, the energy solar is used to load the storage medium of electric power and medium 20 for conversion (not shown) It is a photovoltaic panel. A sensor comprises a photodiode 60 that it is also used as a means 80 to determine the quantity Instant energy convertible into electrical energy. This circuit is controlled by microcontroller 40. An amplifier operational 90 allows amplifying the short-circuit current of the photodiode 60. The voltage at the terminals of a resistor 92 and of a variable resistor 94, placed in series between an input and The output of the operational amplifier is compared to a threshold voltage by means of the microcontroller. This allows, for For example, detect the occurrences and disappearances of the sun. With This purpose can be adjusted variable resistance. A transistor 96 is arranged in parallel with respect to the variable resistance and its "through" or "locked" state corresponds, after the adjustment of the variable resistance, to the presence or absence of the sun.

US 4,695,785 gives, for example, another embodiment of the medium for determination 80, which could be used without departing from the scope of the invention.

Thanks to the invention, a better one is possible anticipation of autonomy problems thanks to an evaluation of the amounts of energy that can be converted into electric power and an electric power consumption adapted to These quantities evaluated.

In figure 1, the dashed connection discontinuous 100 between medium 20 for energy conversion and means 80 for determination means that, in a mode of realization, the functions of these means can be assured by the same element. The dashed connection 110 between the detection means 60 and the means 80 for the determination means that, in one embodiment, the functions of these Means can be secured by the same item.

Claims (5)

1. Operating procedure of an autonomous home automation sensor device (10) to detect the existence and / or to measure the intensity of a first physical phenomenon, comprising a means (20) for the conversion of an effect of a second physical phenomenon in electrical energy, to power the device and a means (80) for the determination of the instantaneous power of the second physical phenomenon, which is convertible into electrical energy, characterized in that a first normal mode of operation of the device is activated or a second is activated operating mode with energy saving of the device, according to a value defined from the determination of the instantaneous power convertible into electrical energy, the device having a lower electrical consumption in the second mode than in the first mode, obtaining the reduction in consumption electrical by means of at least one of the following characteristics:

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the frequency of measurement of the intensity of the first physical phenomenon is greater in the first mode of operation than in the second mode of functioning,

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the frequency of sending status and / or data signals is higher in the first mode of operation than in the second mode of functioning,

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a number of frames emitted in a status signal is greater in the first mode of operation than in the second mode of functioning,

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a logical processing unit (40) works, in the first mode of operation, at a frequency greater than that which works in the second mode of operation,

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a means (30) for storing electrical energy is charged by intermediate of a converter-elevator (70) or directly from the middle for the conversion of an effect of second physical phenomenon in electrical energy according to the level of loading of the storage medium, in the first mode of operation, being permanently loaded the means of electric energy storage directly from the middle to  the conversion of an effect of the second physical phenomenon into energy electric, in the second mode of operation.

2. Operating method according to the preceding claim, characterized in that the first physical phenomenon and the second physical phenomenon are identical. 3. Operating method according to one of the preceding claims, characterized in that the device only emits when the intensity of the first physical phenomenon verifies a predetermined criterion. 4. Operating procedure according to the preceding claim, characterized in that the predetermined criterion can be redefined by the user. 5. Autonomous home automation sensor device (10), characterized in that it comprises material means (20, 30, 40, 70, 80) and computer means for carrying out the operating procedure defined according to one of claims 1 to 4.